Record controlled distributing and accounting machine



R. E. PAGE ET AL Jan. 13, 1948.

-' RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE l2 Sheets-Sheet 1 Filed Dec. 31, 1943 INVENTORS .6. PA GE A'ITORNEY R. E. PAGE ET AL Jan. 13, 1948.

RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE l2 Sheets-Sheet 2 INVENTOR$ PA GE ATTORNEY Filed Dec. 31, 1943 xPALPH E HOBQACE 15. 55A 7775' r 1m 1948- RE. PAGE ETAL 2,434,512

RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE Filed Dec. 31, 1943 12 Sheets-Sheet 3 f; RIC+24CZ I n v 172 170, Fraffaf INVENTORS RALPH E. PAGE HOP/1 c5 5. 554 77/5 ATTORNEY Jm 8- R. E. PAGE ETAL 2,434,512

RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE Filed Dec. 51, 1945 12 sheets-sh 4 ATTORNEY Jan. 13, 1948. R. E. PAGE ETAL RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE Filed De c. 31, 1943 12 Sheets-Sheet 5 E 5 Y 0 E TA N m m mfm .m w A. m

M 3, 948 R. E. PAGE ETAL 2,434,512

RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE' Filed Dec. 31, 1945 l2 Sheets-Sheet INVENTORS RALPH 5. PAGE H AcA S. 654 7775 AJI'TORNEY R. E. PAGE ET AL Jan. 13, 1948.

RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE Filed Dec. 31, 1943 Hrcaffi.

l2 Sheets-Sheet 8 M o o S o 0 ADD/85525 &. AMOUNT X7'RA 51/57. DESCRIPTION M01005 m a! sue-c7750 LIST FROM NAME 04/?0 ONLY F/E'LD FIG. 16

T Y TEWJ M NGA R 45 0 MP5 .w 5 5 H E mmm Am RH R. E. PAGE EI'AL Jan. 13, 1948.

RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING MACHINE l2 Sheets-Sheet l0 iNVENT RALPH ORS PAGE lg/ICE a". 55A 77/5 'ATroRNEY ncc anuur/w a MAG/VETS F 1 :m R u P 5 I; R "M fmw u i a 3 w a M (I y g 0 C C Jan. 13, 1948. R. E. PAGE ETAL 2,434,512

RECORD CONTROLLED ms'rnzaurme AND ACCOUNTING MACHINE Filed Dec. 31, 1943 l2 Sheets-Sheet ll FTGJTQ w INVENTORS RALPH E. PAGE Hag/ 465 5. 55477/5 ATTORNEY Patented Jan. 13, 1948 2,434,512 RECORD CONTROLLED DISTRIBUTING AND ACCOUNTING Ralph E. Page, West Orange,

MACHINE and Horace S.

Beattle, East Orange, N. J assignors to International Business Machines Corporation, New

York, N. Y., a corporation of New York Application December 31, 1943, Serial No. 516,572

The present invention relates to accounting machines of the record card controlled type, and its principal object is to provide a machine in which two separate sets of record cards may be concurrently fed through the machine and data designations thereon sensed by separate sensing devices, to control common recording and calculating mechanisms to prepare a complete bill or statement. I a

In many commercial establishments, it is the practice to maintain a file'of so-called master cards comprising cards containing designations relating to names and addresses of difierent accounts, arranged in alphabetic order and including one or more cards containing additional data. A separate file is also maintained of so-called detail cards, which are arranged in alphabetic order and contain data concerning various transactions. In order to prepare a, bill for each account, it is necessary at the present time with existing facilities to combine the two files into a single file arranged in alphabetic order with master cards adjacent to their related detail cards, and it is then necessary to run the cards through an accounting machine in which the bill is prepared. Following this, if it is required that the cards be returned to their original filing order, it is necessary to separate the master cards from the detail cards. All of this requires three separate operations effected in succession and, where the volume of cards involved is great, the consumption of time is considerable in addition to the possibility of cards getting out of order through such frequent handling.

In accordance with the present invention, a machine is provided in which two files of cards are separately placed and separate feeding and sensing mechanism is provided for each, with comparing mechanism operative to cause the feed and sensing of the cards in the same order of succession as though they had been merged into a. single file and then sensed in succession. Printing and calculating devices are controlled by the cards as they are sensed, and thereafter the cards may be fed to separate pockets in their original order. Thus, the same results that previously re-- quired repeated handling of the cards are effected in a single machine during a single run of the cards therethrough.

Selectively adjustable devices are provided so that, if desired, the two files may be merged into a single file in alphabetic order concurrently with the sensing and recording operations.

According to another feature of the invention, provision is made to separate out into a 11 Claims. (CL. 235-6137) separate pocket master cards for which there are no related detail cards.

A further object resides in the provision of devices for causing master cards, for which there are no related detail cards, to pass through the ing mechanism for determining conditions of equality and inequality existing between data on two opposed cards.

Other objects of the invention will be pointed out in the following description and claims and illustrated in the accompanying drawings, which disclose, by way of example, the principle of the invention and the best mode, which has been contemplated, of applying that principle.

In the drawings:

Fig. 1 is a central section through the card feeding and sensing mechanism.

Fig. 1a is a detail of a magazine card lever and contact.

Fig. 2 is a view showing the driving connections for the card feeding mechanism.

Fig. 3 is a further view of the driving mechanism for the card feeding devices, and the view also shows the location of the several card lever contacts operating devices.

Fig. 4 is an enlarged detail of one of the card feed clutches, the view being a section taken substantially along lines 4-4 of Fig. 2.

Fig. 4a is a diagram showing the order in which the figures of the circuit diagram are to be arranged.

Fig, 5 is an enlarged detail of the parts shown in Fig. 1 for controlling the distribution of cards.

Fig. 6 is a view taken generally along lines 6-6 of Fig. 5.

Fig. 7 is a detail showing the configuration of the ends of the card distributing blades.

Fig. 8 is a view showing the printing mechanism.

Fig. 9 is a view showing the paper spacing mechanism.

Fig. 10 is a. view showing the essential elements one order of the accumulating mechanism. Fig. 11 is a sectional view looking in the direction of lines l|--ll of Fig. 10.

Fig. 12 is a detail of a stepping switch.

THE RECORD CARDS The record cards which control the machine are the well known Hollerith type (Fig. ,5) in which twelve horizontal rows of index point positions are provided. The card is provided with columns in which numerals or alphabetic characters are recorded by single or combinational code perforations by means of which the various characters are represented as follows:

Character Positions Character Positions Accordingly, the card in Fig. is perforated to represent the name John Smith at the left end of the card. For filing and machine control purposes, all record cards bearing any data Pertinent to the account of J ohn Smith will have the same left hand field perforated with the name Smith or, where thesu'rname is not suflicient identification, all cards may be perforated with the full name. A second field of the card is set aside to receive a street address or city and State. A still further field is set aside to receive designations representing an amount. Cards are also provided with columns set aside to receive special perforations in the X indexpositions to represent various: conditions.

Referring to Fig 14, there are represented two files, of cards, themaster file and the detail file, each containing a number of cards relating to the account identified as that of John Smith, and each of the cards contains perforations designating such name. In addition, the cards contain information as follows:

Master card #1 The given name John Master card #2 The street address Master card #3" The city and State Master card #4 Explanatory data and an amount Master card #5 Explanatory data and an amount Of the master cards, the. first three are known as. address cards, and to distinguish them from other master cards the latter. are provided with a special perforation in the X position of a selected column with a perforation designated l0 (Figs. 14 and 15). Where the amount is a debit amount, a further X perforation designated H is made in another predetermined column to tell the machine that this amount is to be subtracted. Finally, each of the master cards which it is desired to have removed from the file during an operation of the machine is perforated with a still further X hole, which is designated l2. In the detail file the cards are all perforated with explanatory data and an amount together with the X hole H in those cards whose amounts are to be subtracted.

Fig. 13 shows abill which is to be prepared by the group of cards in Fig. 14 for the account of Smith. Examination of the bill will show that the cards of the master file are to print the ad- 'dress and that, after line spacing has taken place, the remaining master cards print and then the data from the detail cards is printed on the successive lines. While this printing takes place, the amount fields in the several cards control calculating devices which selectively add or sub.- tract the amounts and control printing of the total on the last line of the bill. As will be explained later, the cards, as they pass through the machine, may be redistributed to cause them to be merged into a single file with the master cards preceding the detail cards to form a single group, or they may be caused to divide out into three groups with the three address cards in one, the fourth and fifth master cards in the second group, with the detail carols remaining in a third group.

The manner in which these operations are carried out will be'fully explained hereinafter. Before explaining the operation of the machine, the separate units thereof will first be briefly explained, after which the operation of the entire organization will be coordinated and the sequence of events explained in connection with the circuit diagram.

CARD FEEDING. MECHANISM Referring to Fig. 1, the master cards are placed in the magazine [3 from which they are fed singly by means of a reciprocating picker M to pairs of feed rollers [5 which advance the cards horizontally past the first set of sensing brushes designated MI and a second set of sensing brushes M2. The brushes MI and M2 make electrical contact throughperforations in the record cards with contact rollers I6 and I1, respectively, which rollers also serve as feed rollers for the cards. The detail cards are placed in the magazine l8 from which they are fed singly by a reciprocating picker- Hi to pairs of feed rollers 20 which convey the cards along an inclined plane past sensingbrushes designated DI and D2 which make contact through the perforations in the cards with contact rollers 2| and 22, respectively.

The lower of the pairs of rollers l5 and the contact rollers l6 and I1 are secured to shafts,

generally designated 23 which at their extremities (see Fig. 2) are provided with gear 24 which mesh with gears 25 on a horizontal shaft 26. In the same manner the shafts 21 which support the upper of the pairs of rollers 20 and the contact rollers 2| and 22 have gears 28 at their extremity (see Fig. 2) which mesh with gears 29 secured to an inclined shaft 30. In Fig. 2 is shown a shaft 3| which is in axial alignment with shaft 26 and which is in constant rotation from a suitable source of power, such as an electric motor (not shown). The shaft 3| may be coupled to drive shafts 26 or 30 through suitable clutching mecha- 5 nism; of which that for the master shaft 26 will nowbe explained.

Referring to Fig. 4, shaft 3| carries a notched driving element 32 at its extremity which accordingly is in constant rotation. Lying in the plane of the element 32 is a clutching dog 33 which is pivoted at 34 to an arm 35 secured to the master shaft 26. The dog 33 is normally urged by a spring 36 toward the driving element 32 but is restrained by engagement with latch 31 which is pivoted at 38 and is integral with the armature 39 of a clutch magnet 40. Upon energization of magnet 40 armature 39 and latch 31 are rocked clockwise about pivot 38 and release dog 33 for driving engagement with element 32, whereupon shaft 26 will be coupled to shaft 3| and the former will be driven for one revolution, at the end of which dog 33 is engaged by latch 37, and further operation is interrupted unless the magnet 40 is held energized. The clutching mechanism shown in Fig. 4 is provided with the usual clutch knockout lever 4| whose roller is engaged by a cam 42 during the rotation of parts to effect positive restoration of the latch 31 and armature 39.

Generally speaking, the-magnet 40 controls a form of one revolution .clutch through which shaft 26 is coupled to the constantly rotating shaft 3|. The shaft 3| .(Fig. 2) through a pair of beveled gears 44 drivesa clutch element 32a which corresponds to the clutch element .32, and through a one revolution clutch mechanism exactly the same as that described for the master shaft. The detail shaft 30 may be coupled for .drivingaction upon energization .of a magnet designated 43 which corresponds to the magnet 40. The shaft 3| through gears .45 and .46jdrives a number of shafts 4'! to which (Fig. 1,) are secured the lower of pairs of feed rollers 48 which are thus in ,constant rotation.

Referring to Fi 3, the right hand shaft 4.! through gearing generally designated 49 drives shafts 50 and 5| in opposite directions. Referring to Figs. 1, 5 and 16, the shaft 50 has secured thereto rollers 52 which cooperate with rollers v53 loose on an intermediate shaft .54, and the shaft 5| has .rellers -55 secured gthereto which cooperate with rollers 56 also loose on the intermediate shaft 54. Through the gear connections traced, it will be noted that the shafts Ell and 5| and the rollers 53 and 56 are in constant rotation so that, :when either the-rnaster or detail card is advanced to such rollers, it will be conveyed to the rollers 48 and thence to one of the .four pockets designated Pl, P2, P3 or P4 in ac- 'cordance with preselected distribution require- .ments which will presently be explained.

In Fig. 2 one of the shafts 23 drives a shaft .51 through gears 58 and one of the shafts ,22' drives a shaft 51a :through gearing designated 59. In Fig. 1 theseshafts-51 and 51a carry cams 60 and 60a. respectively, foroperating their respective cardpickers |,4'-,an,d l9 through the connections shown.

Referring to Fig. 1a, the magazine I3 is provided with the usual pivoted card lever 6| which serves to hold .a pair of contacts 62M closed as long as there are cards in the master magazine -|3. A similar pair of contacts is provided for the detail magazine -|8.which are indicated on the circuit diagram-(Fig. 1 7d) asBZD.

Referring :toFigs. 1 and .5, master and detail .cards aftertheypass the rollers :52, 53, 55 advance toward a set of distributing blades (Fig. 7) which :umdesignated 63,5114, Siam-r66. The blades are to shaft so arranged that normally they occupy the position shown in Fig. 5, wherein all the cards are guided into the opening or passageway between the blades 63 and 64, which passageway guides the cards to the second pocket designated P2 in Fig. 1. The blade 53 may have its end elevated so that the detail card passes below the blade, in which event such card will pass to pocket PI. The blade 64 may have its right hand end depressed below the path of travel of the card, in which event a passageway is formed between blades 64 and 65 through which the master card will be guided to the third pocket designated P3. Finally, the right hand end of blade 65 may be depressed below the level of the master card, in which event as will be apparent from Fig. '7 the blade 54 is also depressed, and the card will enter the passageway formed between blades 65 and 66 for conveyance to the last pocket P4.

By thus shifting the positions of the ends of blades 63, 54 and G5 the master cards may be selectively directed to any of the pockets P2, P3 or P4, and the detail cards may be directed to either of the pockets Pl or P2. In other words, with none of the sorting magnets energized, cards will be directed to pocket P2 and cards will be directed to pockets Pl, P3 or P4 upon energization of magnets S|, S3 or S4, respectively. The mechanism for shifting the blade ends is controlled by magnets designated S l, S3 and S4 (Figs. 5 and 6) whose manner of operation will now be explained.

Magnets S3 and S4 are suitably mounted in a supporting bracket 61 and each is provided with an armature 68. The armatures are shaped to provide 3, lug ,69 and an opening it which are engaged by hook-shaped portions of arms 1| which are pivoted at 12. Thus, each armature 68 holds its related arm 1| normally in raised position, one through engagement with the lug 69 and the other through engagement of its arm with the lower edge of opening -10. The blade operating arm H of magnet S3 has a pin 13 carrying a roller cooperating with a cam 4 secured 5|] and a spring normally tends to cause the roller to follow the periphery of the cam. The cam is so proportioned that the arm H is raised slightly during each revolution of shaft 53, so as to free the hook-shaped portion of arm H from the armature 68 and relieve the magnets S3 and S4 from the frictional load of the parts. The pin 13 cooperates with a notch in arm 1| of magnet S4 to hold said arm up against the tension of its spring '55. Thus, both arms II are controlled by a common cam. If magnet S3 is energized, its arm 3| is released to follow the cam which results in counterclockwise rocking of the related arm 7|. When magnet S4 is energized, its armature 68 through a lug 16 will also rock armature 68 of magnet S3 so that both arms 1| will rock counterclockwise as viewed in Fig. 5. The arms ii are roughly L- shaped with the free ends in engagement with blades 64 and 65 so that, when the arms ll are released by their related magnets, the blade 64 alone or blades 64 and 65 together are shifted to select the passageway to receive the master card.

The magnet SI controls similar mechanism which i identified by the same reference characters followed by the suffiX a. Thus, when magnet S| is energized, it attracts its armature 68a, whereby the hooked portion of arm l'la is released so that a spring 75a will rock the arm clockwise about its pivot --'l2a and the free end of the arm will act upon the end of blade 63 to swing it into position to select pocket PI for reception of the detail card. The shafts 59 and 'are provided with the usual cam for positively restoring the armatures 68 and 68a after they have been tripped.

Referring to Fig. 2, the shaft 3i through one of the shafts s1 and gearing generally designated 'l'l drives a pair of shafts 18 upon which are mounted contact closing devices for operating contacts which are generally designated as C contacts, whose number and timing are shown in Fig. 16. These devices are in constant operation as long as the machine functions. Driven from the right hand shaft 23 through gearing 19 is a shaft 89 which rotates only while the master card feeding mechanism is clutched for operation. On this shaft is located a number of cams for operating contacts which are generally designated as M contacts, and in the same manner the shaft 51a of the detail card feeding mechanism carries a number of cams which operate contacts generally designated as the D contacts whose number and timing are also shown in Fig. 16. Thus, the C contacts are in constant operation, the M contacts function only when the master card feeding mechanism is coupled, and the D contacts function only when the detail card feeding mechanism is coupled.

Referring to Fig. 3, the usual card levers are provided and located in the paths of travel of the master and detail cards. These card levers are generally designated 8!. Each closes a pair of contacts generally designated 82, which close when a card has been advanced to a predetermined distance short of the related set of sensing brushes Ml, M2, DI, D2. These card lever contacts are shown in the circuit diagram (Fig. 17d) in connection with which their function will be later explained.

PRINTING MECHANISM In Fig. 8 shaft E9 is the upper of the two shafts 18 of Fig. 2, and it is, therefore, in constant rotation making one revolution for each cycle of the machine. The printing mechanism driven from this shaft is of a well-known type disclosed in the Fuller et a1. Patent 2,199,561, granted May 7, 1940, and this mechanism will, therefore, be but briefly described. Shaft i8 is geared to shafts 85 and 89 as explained in the patent, so that these shafts are driven two revolutions for each revolution of shaft 18.

Shaft 85 fixedly carries a notched clutch disk 81 and adjacent the clutch disk 8i there is loosely mounted gear 98 to which is pivotally mounted a spring-urged clutch pawl 89, the latter being normally engaged by a clutch release arm 99 so as to hold the clutch tooth 95 out of engagement with a clutch notch of the clutch disk 91.

The above described clutch is the printing type selecting clutch and causes the differential rotation of a printing wheel 92. To rotate the type wheel 92, the gear 99 meshes with an idler gear 93 loosely mounted on a shaft 99, and the gear 93 meshes with the type carrying wheel or gear 92 carrying the digit printing type 0-9 inclusive and comprising the numeral type group, the numeral type being spaced four teeth apart. Fig. 8 shows the arrangement of the printing devices for a single order and the machine is preferably provided with duplicate devices for printing the digits of different denominational orders.

The card is perforated with holes to represent the digits 0-9 and passes by the analyzing brushes M2 or D2 (Fig. l) to analyze the index points in the order 9, 8, '7, 0. When the analyzing brush M2 or D2 senses a hole, a circuit is closed to a printing control magnet 95, and for each card column analyzed there is a printing control magnet. When a printing control magnet 95 is energized, its armature 96 is attracted so as to pull a call wire 91 to the right. The latter has a head portion comprising extensions 98 and 99, the extension 98 normally engaging a lug of an arm I00 which is the integral depending part of the clutch release arm 99. The normal engagement of extension 98 and arm Hill is retained during the time the holes 9, 8, 7, 6, 5, 4, 3, 2, and l are analyzed to thereby cause the clutch release arm 99 to be rocked. The clutch pawl 89 is now rocked by its spring to cause its tooth 9| to engage a particular notch of the clutch disk 81 to thereby cause the gear 38 to be rotated and through the idler gear 93 rotate the printing gear wheel 92.

If the 9 or first hole was analyzed, the clutch disk 81 would rotate the extent of one notch before the clutch engagement is effected b the energization of the magnet 95. The printing wheel 92 will thereafter rotate so as to bring the 9 numeral type to the printing line.

In the above manner the printing type wheels are picked up at differential times so that at a predetermined point in the cycle of machine operation the printing wheels will represent at the printing line the selected digits, it being noted that the 0 type is normally at the printing line so that no movement of a printing wheel is nocessary to select 0 for printing.

It will be seen that the free end of the call wire 9'! passes between a rod l9! and a bar 102 of a bail shaped frame which is pivoted at I93. One side arm of the bail shaped frame has a depending follower arm I94 carrying a roller I95 coacting with a cam I06 secured to the shaft 18. After the 1 index point is analyzed, the 0 hole is sensed by the analyzing brush if it is present, but before analyzing the 0 hole an inclined cam edge lilEa of a high portion of cam I99 acting on the follower arm I04 rocks the bail shaped frame clockwise, causing the rod lfii and bar [02 to depress all the free ends of the call wires 91 so as to disengage the extension 98 from the lugs of arms I and to engage extensions 99 with lugs H9 of arms H3 so that, when a 0 hole is sensed, magnet will through call wire 91 and lug 99 rock arm H3 for the purpose explained later in connection with alphabet printing. Obviously, with this relationship even though a magnet 95 is energized by the presence of a 0 hole, the printing type selecting clutch for rotating the printing wheel will not be engaged so that, when the printing impression is effected, the 0 digit will be printed,

Each printing wheel is carried by an arm I01 loosely pivoted on the shaft 94 and is provided with follower arms H38, each of which engages a related cam of a pair of complementary cams I09.

There is a printing clutch for each printing wheel for causing the impression to be effected and this is similar to the previously described printing type selecting clutch and comprises the clutch disk H9, a clutch pawl I H carried by one of the complementary cams I99 and a clutch release arm HZ having an integral depending arm H3.

For each printing wheel that is set to any digit from "1 to "9", a cam I I4 attached to a related gear 93 will rock a double arm II5. One end of each arm II5 carries a pin IIB engaging a slot of a link II I, the latter being pivoted to an interposer IIB, a series of the interposers II8 being pivoted on a rod II9a. Obviously, when the double arm H5 is rocked by the cam II4, the link I" is depressed to rock th related interposer I I8 to bring its free or right end in front of a lug II9 of the arm H3.

The interposers II8 are carried, as stated, by the rod II9a and the latter is carried by a pair of depending arms I20, one of which is provided with a projection I2I coacting with a profile cam I22 secured to the shaft I8.

After all the index points of the card which comprises the index point 0-9 and the special index points x and R have been analyzed, the projection I2I will drop from the high part of the cam I22 to a low part permitting a spring I23 attached to an arm I20 to shift all the interposers II8 to the right and those that have been rocked by the depression of a related link I" will by their shifting rock the arms I I3 and, therefore. the clutch release arms I I2, causing the clutch engagement so that complementary cams I09 will now rotate to rock all the arms I01 to force the printing wheels 92 against the usual inking ribbon and platen I24, around which is fed a paper to be imprinted.

As each arm I01 is rocked, the printing wheel is rotated counterclockwis but, since the printing wheel is rolling over the gear 93, this rolling act on will cause an equal and simultaneous rotation in a clockwise direction. Both of these opposite rotations will, in effect, cause the printing wheel 92 to be substantially stationary when it strikes the platen I24, the type striking the latter squarely and firmly to cause a legible impression.

After the printing operation, since the clutch is still en aged, the printing wheels continue to rotate until the clutch pawl 89 strikes the clutch release arm 90, thereby disengaging the clutch which is effected when the printing wheels are at 0. The clutch which causes the rotation of the cams I09 to effect the imprint continues its engagement for a complete rotation of the cams I09 and the clutch disengagement is effected by the engagement of the clutch pawl III with the arm H2.

The machine i provided with alphabet character printing type and means for selecting such type so as to print, aside from numerals, letters making up words or abbreviations.

The alphabet type are selected according to groups. The particular group selected determines which of the several ty e related to an index point will be printed. For example, if the perforation should be the "2 hole. and no pilot hole is utilized in either the "0, X" or R positions, 2 will be printed. If a hole is also at "0, the "0 hole will select the type S. If at the "X index point position type K will be selected. and if at the R index point position type B will be selected.

To more clearly understand the principle of operation, it should be noted that from the timing of cam I 22 the selected numeral type have their impressions taken therefrom after all the index points have been analyzed and, of course. is after the R index point has been analyzed. The alphabet type selection is provided for by taking the printing impression before the time numeral type would have been printed, and this from the I type.

10 is effected under control of the index points "0, (X), R!!- If the hole was at the 9 index position alone, the printing wheel 92 would rotate counterclockwis until 9 was at the printing line and then the printing wheel carrying arm I01 would be rocked to effect the imprint. It will be noted that, if a perforation was at the R position and, then, under control of this perforation, the printing impression clutch IIO, III was engaged, the printing wheel 92 will be rocked earlier than for printing a numeral "9 to take an imprint The perforation at the "X position will take an imprint some time earlier to print R and the perforation at the 0 position still earlier to print Z. The same principle of operation is provided for selecting the other alphabet type.

Obviously, the energization of a magnet will, after the 1 perforation is analyzed, cause the arm II3 to be rocked and the clutch release arm II2 to be rocked, and at a time depending upon the pilot hole analyzed. Hence, the type printing clutch IIO, III will be released to cause the printing impression from the selected type.

It is pointed out that for alphabet type printing, impressions are mad-e at three different points in the operation cycle or after the 0, X and R perforations are analyzed, whereas for numeral printing the impressions are made only after all the perforations are analyzed and at a single point in the operating cycle.

PAPER LINE SPACING Referring to Fig. 9, the platen I 24 has the usual spacing ratchet I26 secured thereto, with which there is associated the usual detenting arm I21 and pawl I 28. Pawl I28 is pivoted upon bell crank I29 connected to a depending link I30, the lower end of which is provided with an L-shaped slot through which a pin I32 extends. The armature I33 of a magnet I34 normally holds the lower end of link I30 toward the right as shown. Pin I 32 is carried by one arm on the three-arm lever I35 0 which is oscillated by a cam I36 on shaft I8, so

that for each revolution of the shaft pin I32 moves up and then down again. With the link I30 latched in the position shown, the pin moves idly in the vertical part of slot I3I without disturbing the position of the link. When magnet I34 is energized, the link I 30 is released and a spring I 31 shifts the same to bring the right end of the notch I3I into line with pin I32, so that, when the pin is now moved up, it will elevate the link I 30 to effect paper line spacing. The shaft I8 also carries a disk I38 in which is secured pin I39 that engages a bell crank lever I40 whose pin I-II will rock link I30 back to its latched position after the paper spacing operation.

ACCUMULATING MECHANISM The machine is provided with adding mechanism, of which one denominationalorder is shown in Fig. 10. This mechanism is also driven from the constantly running shaft 18 through a gear 84 mounted on the shaft. This accumulating mechanism is of a well known type shown in Patent 2,165,288, granted July 11, 1939, to which reference may be had for a more detailed disclosure. A brief description of the operation thereof will accordingly be suflicient herein.

The gear 84 on shaft 18 drives gear I42 (Fig. 11) freely about a post I 43, and driven by gear I42 is a ratchet I44 which is axially movable but normally held in the pos tion shown in Fig. 11 by a f Sp g I45. Coaxial with driving ratchet I44 is a ratchet I45 which is part of the accumulating or adding element comprising adding wheel I41 and tens carry cam I48, which are in egral with a rod I49. Ratchet I44 may be rocked into engagement with ratchet I45 to drive the l tter and such rocking is effected by a bevel disk I59 carried by a bell crank II, which is normally latched in the position shown in Fig, by the armature I52 of adding magnet I53. When magnet I53 is energized, bell crank I5I is released and spring I54 will rock it to move disk I toward the axis of ratchet I44, thereby camming the ratchet I44 into driving engagement with the driven ratchet I 45. The gear I42 carrie rollers I55 the first of which engages an extension of lever I5! to effect uncoupling when the first roller reaches the extension of the lever. If a unit is to be carried from a lower order, magnet I53 is reenergized to effect a new driving engagement and. after one step of movement, the second roller I55 will engage lever I 5i to effect uncoupling after such carry entry operation.

As usual, magnet I 53 is energized at differential times, i. e. one, two, three, etc. up to nine socalled cycle points before the first roller I55 effects uncoupling, so that the digital value entered into wheel I41 is dependent upon such time of energization of magnet I53. Thus, if a '7 is to be entered. magnet I53 is energized seven points before the knockout position and wheel I41 will have been advanced seven steps. The carry cam I48 controls the usual tens carry contacts comprising movable contact blade I59 and stationary blades I65 and 5!. which functions so that whenever the wheel I41 passes from 9 to 0 member I52 is rocked clockwise and held by latch I63 as shown in Fig. 10 to hold blade I59 in engagement with blade I60.

Whenever the wheel I41 stands at 9, a depression in the wheel will permit the member I62 to rock counterclockwise, thereby enabling blade I59 to rock clockwise and engage the blade IBI. The roller 555 is provided for releasing carr lever latch I 53 at the end of the cycle. The carry con-- tact blades I59, I are utilized for canceling or clearing the adding wheel. This is eilected as follows: Ma net I53 is energized at a time to cause the wheel I41 to be driven ten steps, during which the wheel will pass from 9 to 0 with the resulting engagement of blades I59 and IE9. As will be explained in connection with the circuit diagram. such contact engagement will cause energization of the so-called subtracting magnet I64. magnet attracts its armature I65 to release lever I66 for counterclockwise rotation about its pivot I51 under the influence of spring I54. Pin I68 in the lever will thereupon en age and rock bell crank I5! clockwise to uncouple the ratchets and leave the wheel I 41in its 0 or home position. The usual IOllel I51 is provided which en a es and res ores the lever I56 to its normal position.

When an amount is to-be subtracted, the adding magnet I 53 is energized at a time appropriate for adding the digit 9 and thereafter the subtracting magnet I54 is energized at a timecorre ponding to the value of the amount. of the digit to be subtracted, the net result being that the wheel I41 is advanced an amount corresponding to the 9s complement of the digit to be subtracted. Thus, for example, if the digit 7 is to be subtracted, the adding magnet is energized at the 9 time and wheel I41 commences to rotate as though to advance nine steps. After it has advanced two This ' occur.

steps, however, the subtracting magnet is energized and uncoupling is effected, thus leaving the wheel I41 advanced two steps in accordance with the 9's complement of 7.

STEPPING SWITCH In Fig. 12 is shown a well known form of stepping switch which is utilized in programming the operations of the machine, and a brief explanation of this device will be given. The stepping magnet designated SM, when energized, will rock its armature I10 to which pawl I1I is pivoted so that the pawl will engage and advance ratchet I12. Secured to the ratchet is a switch arm I13 which for each step of advance of the ratchet will contact a different one of a series of contact segments I14. The ratchet I12 is normally biased to rotate counterclockwise by the usual spring, not shown, and is restrained from doing so by the latching armature I15 of release magnet RM, which magnet when energized will rock its armature out of engagement with the ratchet, so that the same will swing back to its initial or starting position shown in Fig, 12. For the purpose of the invention, the ratchet I12 has two arms I13 and two sets of contacts I14 associated therewith which are shown diagrammatically in Fig. 17d, where the second set is identified as H311 and H411. The circuits controlled by these stepping relays will be explained in connection with the circuit diagram.

CIRCUIT DIAGRAM The circuit diagram (Figs. 17a to 17d) will now be explained with particular reference to the problem outlined in connection with Figs. 13 and that is, in explaining the diagram it will be assumed that two files of cards, as in Fig. 14, are placed in the machine and during its operation the two files of cards will jointly control the various mechanisms to prepare the bill or invoice of Fig. 13. The description will be subdivided into cycles of operation, and the sequence of operations will be explained in the order in which they In the circuit diagram a system of identification for the relay magnets is followed wherein the contacts are given the same reference character as the controlling magnet followed by a lower case letter. In most cases the contacts are shown adjacent to their controlling magnets. In a number of instances, however, where it would unduly complicate the circuit connections, the contacts are shown remote from their controlling magnets. In such instances, the system of identification will serve to identify the elements and in addition, where a magnet and its contacts are separated, the magnet is shown in dotted outline adjacent the related contacts. The various cam controlled contacts identified as C, D and M contacts have their timing shown in Fig. 16 which is to be considered in connection with the circuit diagram.

PRELIMINARY OPERATION Several plug connections indicated by dotted lines in the circuit diagram are first made to as sociate the fields of the cards with desired positions of the adding and. printing devices. The group of master cards of Fig. 14 is placed in magazine I3 (Fig. 1) and the group of detail cards is placed in magazine I8. The bill of Fig. 13 is placed around the platen I24 (Fig. 8) with its line I in printing position. With these preliminary operations effected, current is supplied to main line designated I in the circuit diagram, Figs.

13 17a and 17b, and as a. result the main driving motor (not shown) is placed in constant operation to continuously drive the main shaft 3I (Fig. 2) and the C contact cams.

If the start key is now depressed to close contacts I16 (Fig. 1711), a circuit is traceable from line I80, stop key contacts I11, contacts C2, I16, start relay ST and thence to ground I90. Relay ST closes its contacts S'Ia to provide a holdin circuit traceable from line I80, contacts I11, mag

azine card lever contacts 62M and 62D, contacts STa, relay ST to ground I90. The relay ST will accordingly remain energized until the stop key is operated or cards run out of either magazine. The usual contacts C3 short circuit contacts I11, 62M and 62D, so that, if any of these contacts open, their circuit will nevertheless be held until contacts C3 open at a definite time in the cycle (see Fig. 16)

Shortly after relay ST is energized, contacts C6 close and complete a circuit from line I80 (Fig. 17a), contacts C6, wire I18 (Fig. 170), right hand contacts MICLc and DICLd in paralel, relays LD and HD in parallel to ground I90. This circuit is completed each cycle prior to the operation of the start key but is of no effect until the present cycle. Now with contacts STd closed (Fig. 17d), a circuit is completed near the end of the cycle when contacts C4 (Fig. 17d) close which is traceable from line I80 (Fig. 17d), contacts C4, STh, wire I19, and in parallel through contacts HDc and LDc, right hand contacts PS1 and PS7, master and detail clutch magnets 40 and 43 to ground I 90.

Cycle 1 With both card feed clutch magnets energized, the M and D cam contacts function, and during the cycle now ensuing the first M and D cards are advanced from magazines I3 and I9, respectively, and their leading edges fed to a point between brush MI and the second set of rollers I5 for card M and to a point between brush Di and the second set of rollers 20 for card D, which advance is not suflicient to operate the card levers, so that at the end of this cycle the card lever contacts 82 are still open. Contacts C6 will again cause energization of relays LD and HD so that, when contacts C4 close at the end of the cycle, the clutch magnets 40 and 43 are again energized to initiate a second card feeding cycle.

Cycle 2 During this cycle, the first M and D cards continue their advance toward brushes MI and DI, and before reaching the brushes they close their respective card lever contacts 82 whereupon circuits are completed in Fig. 17d from line I80, the second and fourth contacts 82 from the right, relays DICL and MI CL to ground I90. These relays close contacts DICLa and MICLa, respectively, to provide holding circuits through contactsDI i and MI I which, as seen from Fig. 16, overlap the period of closure of the card lever contacts so that from this point on the relays will remain enersized as long as cards continue to follow.

Card comparing through brushes M1 and D1.- As the two cards pass brushes MI and DI, the index point positions are sensed at the times indicated in Fig. 16 along the line designated "brushes at the points 9, 8, 7, etc. and for brush MI a circuit is partially established which is traceabe in Fig, 17a from line I 80, contacts CI. MI, MICLb (now closed), contact roller I6, brush MI, plug connection I 8| to a socket I 82. A par- 14 allel circuit is also traceable from line I80, contacts CI, D3, DICLb, roller 2|, brush DI, plug connection I83, to socket I84. Only a single connection I 8| and I83 is shown as representative, but it is to be understood that there is a separate such connection to additional sockets I82, I84 (Fig. 170) from each brush DI and MI traversing the name columns of the cards.

Before completing the tracing of the circuits, reference is made to Fig. 170 wherein contacts CI2 to CI1 are shown and to Fig. 16 from which it is seen that contacts CI2 close as the 7, 4 and 1 positions on the cards are sensed, contacts CI3 close as the 8, 5 and 2 positions on the cards are sensed, contacts CI4 close as the 9, 5, 4 and 3 positions on the cards are sensed, contacts CI5 close as the 9, 8, 7 and 6 positions on the cards are sensed, contacts CI 6 close as the 0 and X positions on the cards are sensed, and contacts CI1 close as the 0 and R positions on the cards are sensed.

Accordingly, relays RI, R2, R3, R6, RX and RR are energized at times when their connected contacts CI2 to CI1 close as is apparent from Fig. 170. These relays close contacts shown in vertical alignment therewith in Figs. 17a and No and designated RIa, R2a, etc.

Assuming the columns sensed to contain the letter S represented by perforations in the 2 and 0 positions (see Fig. 15), then when the 2 hole of the master card is at brush MI the circuit already partially traced continues from socket I82 (Fig. 17a), through wire I85, contacts RZa (now closed), one winding of a double Wound relay R2M to ground I90. At the sam time, the circuit from socket I84 continues through wire I86, another pair of contacts R2a, relay R2D to ground I90. Later in the cycle when the 0 hole is sensed parallel circuits are traceable from sockets I82 and I84, wires I85 and I86, contacts RXa, RRa, relays RXM, R253, REM and RRD to ground I90.

For a second comparison column of the example chosen, the column of the card containing the letter M (Fig. 15) would have its sensing brushes connected to sockets I82, I34 of Fig. I10 and since for this letter perforations are made in the 4 and X positions, relays RIM, RID, RBM and R3D will be energized upon sensing of the 4 hole and relays RXM and RXD will be energized upon sensing of the X hole. These relays are the ones shown in Fig. 170, of course. Whenever one of the relays sufiixed M (as relay RIM) is energized it closes contacts sufiixed a (as contacts RIMa) which provide a holding circuit through the sec ond winding of the relay traceable for example, from line I (Fig. 17a) contacts M6, wire 89, contacts RIMa, relay RIM to ground I99. Similarly the relays sufiixed D (as relay RID) when energized close contacts suffixed a (as contact RIDa) to provid a holding circuit from line I80, contacts D6, wire I81, contacts RIDa, relay RID to ground I90.

In the case of relays RXD and RRD the holding circuit is from contacts D6, wire I81, one of the contacts suffixed b of relays RID to RED, wire I88, contacts RXDa or RRDa to these relays and to ground I90. Likewise in the case of relays RXM and RRM the holding circuit is from contacts M6, wire I89, one of the contacts snfiixed b of relays RIM to REM, wire I9I to relay RXM or RRM to ground I90. In accordance with this relay system, as explained, the digits 9 to 1 cause energization of combinations of the relays prefixed R R2, R3 or R6 and the designations 0, X

16 RXD, R31) and RID for letter M in the detail. card.

The resulting circuit established upon closure of contacts C6 would be the same as already 3 traced in Fig. 17a and continue through wire I92,

Character Relays Character Relays A RRM, RIM RXM, RIM. B RRM, R2M RXM, IBM. RRIVI R31 RXh/T, RBM.

RIM, RGNI. 32M, RGM. R3M, 116M.

These relays, when energized, remain so until the following cycle when contacts M6 or DB open and they also shift contacts shOWn at the left in Figs. 17a and 170 which contacts are suffixed c and d. These contacts are interconnected to form what may be termed a comparing chain through which a determination is made as to whether the columns sensed are alike and if unlike which card contains the higher valued designation in the alphabetic or numeric sequence.

For the example chosen the relays are energized in accordance with the name Smith in both the master and detail cards so that the following relays in Fig. 17a will be in energized condition after all positions of the two cards in the columns containing the letter S have been sensed.

RRM, RXM and RZM for the master card and RRD, RXD and RED for the detail card.

The letter M in the next column will have caused energization of the following relays of Fig. 170.

RXM, R3M and RIM for the master card and RXD, RED and RID for the detail card.

Only two sets of the relays are shown and it will be understood that further sets are provided to take care of additional comparing columns.

When contacts C6 (Fig. 17a) close near the end of the cycle, a circuit, as emphasized by heavy lines, will accordingly be traceable as follows: From line E88 (Fig. 17a) contacts C6, contacts RXDc (right), RXMd (right), RRDc (right), RRMd (right), RfiDc (left),ROMc (left), R3130 (left), RBMc (left), R2130 (right), REMd (right), RiDc (left), RIMc (left), wire I92 (Fig. 170) contacts RXDc (right), RXMd (right), RRDc (left), RRMc (left), REDc (left), RfiMe (left), RSDc (left), R3Mc (left), R2Dc (left), R-ilvlc (left), RIDc (right), Ell /id (right), Wire I93, contacts DICLc (now closed) relay E to ground I90.

, Whenever the columns compared have the same designations therefor, relay E is energized. To show what occurs for conditions of dissimilarity, let it be assumed that the same two columns of the master card contained the letters ST and the detail card contained the letters SM.

As a result, th relays of Fig. 170. would be energized in the same combinations as before for the letter S. The relays in Fig. 170 would be energized as follows:

RRM, RXM, RBM for letter T in the master card.

Fig. 170, contacts RXDc (right), RXMd (right), RRDc (left), RRMc (right), wire I94, contacts MICLc (now shifted), relay LD to ground I90. This relay LD is thus energized whenever the detail card is the lower in value or alphabetic sequence, of the two cards compared.

To illustrate the third condition wherein the detail card is greater than the master card, let it be assumed that the master card contains the letters SM and the detail card contains the letters ST. As a result, the relays of Fig. 17a would be energized in the same combinations as before for the letter S and the circuit would run from contacts C5 to the equals wire I92. The relays in Fig. would be energized as follows:

RRD, RXD, R3D for letter T in the detail card.

RXM, REM, RIM for letter M in the master card.

The resulting circuit established would then continue from wire I92 (Fig. 170) contacts RXDc (right), RXMd (right), RRDc (right), RRMD (left), wire I95, contacts DICLd (now shifted),

relay HD to ground I90. This relay HD is thus energized whenever the detail card is the higher in value or alphabetic sequence of the two cards compared.

For the problem of Fig. 14, therefore, the equal relay E becomes energized upon closure of the testing contacts 06. Relay E closes it contacts Eb (Fig. 17:1) to energize the program start relay PS which in turn closes its contacts PSb to provide a holding circuit through contacts G5 which (see Fig. 16) will maintain the relay energized throughout the following cycle. A parallel holding circuit extends from line I80, contacts RELc, PSI) and relay PS to ground. This circuit is maintained until relay REL is energized as explained later underthe heading Cycle 18.

Relay E also closes a pair of contacts Ea (Fig. 17d) through which a circuit is now traceable from line I80, contacts C4. STb, switch arm I13, the 1 segment I14, plug connection I96, contacts RI9b, Ea, PS1, master feed clutch magnet 40 to ground I90. As a result, the master card continues to feed for another cycle and the detail card feed stops as there is no circuit now available to energize clutch magnet 43. The detail card setting is held in the comparing relays, while master cards are being fed because of the fact that contacts D6 (Fig. 17a) are in closed position when the detail feed stops. 

